A particle of mass `m` and charge `q` enters a magnetic field `B` perpendicularly with a velocity `v`, The radius of the circular path described by it will be

A charge q enters into a magnetic field (B) perpendicularly with velocity V. The time rate of work done by the magnetic force on the charge is

A charged particle of mass m and charge q enters a magnetic field B with a velocity v at an angle theta with the direction of B . The radius fo the resulting path is

A particle of mass m, charge e and velocity v moving in a magnetic field B perpendicular to the motion of particle. The radius of its path is:

A particle of mass m and charge +q enters a region of magnetic field with a velocity v, as shown in Fig. 1.93. a. Find the angle subtended by the circular arc described by it in the magnetic field. b. How long does the particle stay inside the magnetic field? c. If the particle enters at E, what is the intercept EF?

A particle of mass m and positive charge q, moving with a uniform velocity v, enters a magnetic field B as shown in Find The radius of the circular are it describes in the magnetic field. (b) find the angle subtended by the arc at the centre. (c ) How long does the particule stay inside the magnetic field? (d) Solve the three parts of the above problem if the charge q on the particle is negative.

A proton , a deuteron and an alpha -particle enter a magnetic field perpendicular to field with same velocity. What is the ratio of the radii of circular paths ?

A proton and an alpha -particles enters in a uniform magnetic field with same velocity, then ratio of the radii of path describe by them

A proton of mass m and charge q enters a magnetic field B with a velocity v at an angle theta with the direction of B .The radius of curvature of the resulting path is